JPH0631748U - Oxygen enriched gas supply device - Google Patents

Abstract

(57) [Summary] [Purpose] An object of the present invention is to provide an oxygen-concentrated gas supply device (hereinafter referred to as a supply device) that is small and lightweight and suitable for carrying. [Arrangement] The AC power supply unit, the storage battery, and the supply device are made into separate blocks, and each block is configured to be separable or connectable with each other. The storage battery can be charged even during use.

Description

[Detailed description of the device]

[0001]

[Industrial applications]

 The present invention relates to an oxygen-enriched gas supply device, particularly a medical oxygen-enriched gas supply device (hereinafter simply referred to as a supply device) for use in home oxygen inhalation therapy for patients with chronic respiratory failure (hereinafter simply referred to as patient). Regarding improvement.

[0002]

[Prior art]

 A supply device used by a patient for home oxygen inhalation therapy includes a pressure fluctuation adsorption method (hereinafter referred to as PSA method) and a selective oxygen method as means for separating and concentrating oxygen gas in the air by the supply device. There is a permeable membrane method (hereinafter referred to as a membrane method), and most of these are used by operating the supply device with a household AC power source.

On the other hand, in order to improve the quality of life (hereinafter, referred to as QL) of a patient who needs such a supply device more comfortably and constantly, he or she can go outdoors and take appropriate exercise or exercise. There is a need for a portable supply device that is easy to travel, and that is small, lightweight, and inexpensive that can be used for visiting hospitals and shopping.

Currently, the most widely used portable oxygen supply source is oxygen gas filled in a high-pressure gas container (cylinder), which is stored in a small iron or aluminum container that can withstand high pressure. It is filled with a high pressure of 150 kgf / cm ² · G, decompressed to a desired pressure (about 1 kgf / cm ² · G) with a pressure reducing valve, and then taken out. The patient inhales and uses the oxygen gas.

The disadvantages of oxygen inhalation by this high-pressure gas container are that the weight of the device is heavy, the filling capacity is small, and the amount is limited. As a result, it cannot be used for a long time, so it is not possible to go far away. Furthermore, there are many safety problems when using in a public transportation or in a car such as an automobile because the range of action and the usage time are limited and a container filled with high-pressure oxygen gas is used.

Another portable oxygen source is liquid oxygen. This is to fill liquid oxygen into a container, vaporize it, and use the vaporized oxygen gas for inhalation therapy while cooling the container itself by the heat of vaporization. Since it does not use a gas container that is as expensive as a gas container, it is lightweight and has a large capacity (converted to vaporized oxygen gas) compared to the above high-pressure gas container and can be used for a longer period of time. It has become.

However, there are disadvantages when this liquid oxygen is used as a supply source of oxygen gas. One is that liquid oxygen is needed to replenish, and this liquid oxygen is not everywhere. Another drawback is that even if the liquid oxygen is not used for inhalation therapy, if it is left for a certain period of time, the liquid oxygen is consumed by natural vaporization and oxygen gas cannot be supplied. In particular, in the summer when the ambient temperature is high, the liquid oxygen disappears in a relatively short time.

When the patient goes out for an excursion, a visit to the hospital, shopping, etc., the car society is now common, and as a matter of course, the patient often uses the car. In addition, it is known that this patient becomes suffocated due to lack of oxygen content in blood as soon as he / she has strong exercise or heavy objects. Therefore, portable feeding devices need to be as small and lightweight as possible.

When taking a short trip to improve the QL of a patient, a free destination can be selected without taking into consideration the place and place of supplementation of oxygen gas, and the action method is also available. It is strongly desired that the range of activities for cars, trains, or on foot can be wide-ranging not only at home but also at travelers and hotels.

[0010]

SUMMARY OF THE INVENTION In order to solve the above-mentioned problems in the conventional supply device, a portable, small-sized device that can expand the range in which it can freely move in order to improve the QL of the patient is provided. It is necessary to provide a feeder.

[0011]

[Means for Solving the Problems]

 In order to achieve the above-mentioned purpose, the present invention has been achieved as a result of analyzing and examining the behavior of the patient and focusing on the size and weight reduction and the power supply system that meet the requirements.

In order to operate the above-mentioned portable type supply device, it is necessary to supply electric power. And since it is portable for the patient's outing, it needs to be small and lightweight and still work while in transit. The usage is roughly classified into the following three points. When there is no external power supply, such as when walking or using public transportation vehicles. When using a car (other than a rental car). When using the AC power supply at home, inns, hotels, etc.

As described above, the supply device includes a membrane system and a PSA method as means for separating and concentrating oxygen gas in the air by the supply device. The former has the advantage that the concentration of concentrated oxygen gas (volume ratio, the same applies hereinafter) is about 30-40%, and the weight of the supply device is slightly lighter than the latter. On the other hand, the latter PSA method has a high oxygen gas concentration of about 95%. Therefore, doctors can prescribe with the same feeling as medical oxygen used in hospitals.

The oxygen gas obtained by these supply devices is inhaled using both a nasal cannula and an open-type oxygen mask, but when an open-type inhaler is used, the oxygen gas Since the gas mixes with the outside air, in order to prevent the oxygen concentration in the lung from differing between these two, when using the PSA method supply device as compared to the membrane type supply device, That is, the flow rate of the oxygen gas may be half or less.

When the above-mentioned portable supply device is used, depending on the method of use, it is operated by using a rechargeable storage battery. However, the weight of this storage battery accounts for a very large proportion of the total weight including the supply device, and the determination of the electric capacity of this storage battery is very important.

When the continuous use time is extended, the electric capacity is increased, and the volume and weight are inevitably increased. If the weight is reduced (lightened), the continuous use time becomes shorter. Therefore, from the viewpoint of automobiles as a means of moving patients, bases such as homes, hospitals, and inns that can be charged from an AC power source, and the practical action ability of patients with relatively weak physical strength, continuous operation within a fixed time Use time. The minimum required time was determined to be 2 hours as a result of surveying many patients. Then, it was concluded that an appropriate electric capacity of the storage battery that can handle the minimum required continuous use time is 20 Ah or less. Further, in order to omit the voltage conversion means which consumes unnecessary power and becomes large in shape, the voltage of the DC power for driving the supply device is set to the voltage of the storage battery of the automobile (usually 12 V, but the engine speed or Depending on the current value of the load, it may be 10V to 15V).

In the case of traveling using the automobile, the vehicle is connected to the DC power source of the cigarette lighter socket of this automobile to operate the supply device, and to the storage battery for driving the supply device. It is configured so that it can also be charged. Since oxygen gas can be supplied from the supply device while traveling in a car, there is no concern that this oxygen gas will be consumed and lost like the oxygen gas of the above-mentioned high pressure gas container and liquid oxygen, and during the next walk Therefore, the storage battery for driving the supply device can be charged by using the generator (dynamo) of the automobile.

If oxygen is inhaled by using the above-mentioned high-pressure container or oxygen gas of liquid oxygen in a room that is relatively narrow and substantially sealed like an automobile, oxygen is not consumed during exhalation. Therefore, it is necessary to take appropriate measures such as ventilation in terms of safety.However, the oxygen gas inhaled from the supply device separates oxygen in the air even if the remaining gas fills the room. As a result, the exhausted gas is enriched with nitrogen in an amount equal to the amount of nitrogen removed to enrich the supply gas with oxygen. There is also an advantage that it is not necessary to consider the fact that oxygen gas fills the room because it does not change.

Where the household AC power supply can be used, the storage battery for driving the supply device can be charged while operating the supply device with the DC power obtained from the AC power supply.

In general, since a patient has a weak physical strength, a device related to the supply device while moving, and a device which is not necessary for the time being (for example, an AC power supply unit operating with a storage battery) can be separated and lightened and carried. did. That is, when using a car to go out and there is no walking section, or even if there is a section to walk, it is extremely short (for example, when visiting a hospital, use AC power at home and When using a DC power supply and receiving oxygen inhalation at the hospital upon arrival at the hospital, etc.), only the main body of the supply device is used, and the storage battery and AC power supply can be separated or combined. . In addition, if the supply device is required even when walking, the storage battery and the supply device can be combined to separate only the AC power supply unit, reducing the overall weight of the supply device carried by the patient. It has a configuration that can be achieved.

[0021]

【Example】

 Hereinafter, an embodiment of the present invention will be described with reference to the drawings. However, this is for the purpose of description, and the present invention is not limited to this embodiment. FIG. 1 is a system diagram of a supply device according to the present invention, and 10 is a supply device, which is constructed by the well-known PSA method. Here, in order to reduce the size and weight of the supply device, which is one of the objects of the present invention, the oxygen gas used for inhalation is synchronized with the breathing phase and is blown during the inspiration phase or only a part thereof. The so-called respiration-synchronized oxygen blowing method, which is a well-known technique, is adopted. As a result, the oxygen gas that is unnecessarily dissipated during exhalation is eliminated, and the substantial average flow rate of the oxygen gas can be reduced, so that the supply device can be made even smaller and lighter. Configured to. In addition, when there is no respiratory signal, or when the oxygen gas flow rate is relatively small and respiratory synchronization is not required, it was configured to be a normal continuous flow.

Reference numeral 16 is a block of a storage battery, and 18 is an AC power supply unit, which lowers a domestic AC power supply (generally 100 V, 50/60 Hz) with a transformer, rectifies it, and drives the supply device 10. The storage battery 16 can be charged. The connection between the blocks was made with the connection connector 14.

In FIG. 1, the block of the supply device 10 and the block of the storage battery 16 are directly connected to each other by the connecting connectors 14, and although not shown in the figure, these blocks can be connected to each other (for example, a patch lock). In addition, the block of the storage battery 16 and the block of the AC power supply unit 18 were connected by a joining cable 26. The storage battery 16 is a sealed lead-sealed storage battery that can be rapidly charged.

FIG. 2 is a system diagram showing another embodiment of the feeding device of the present invention, which is basically the same as the first embodiment shown in FIG. 1, but the characteristic difference is that In the first embodiment, the blocks of the storage battery 16 are independent, whereas in the second embodiment, the storage battery 16 and the supply device 10 are the same block.

In these embodiments, since the block of the storage battery 16 is independent in the first embodiment, another block of the storage battery can be prepared so that the backup battery can be always charged. However, a connection mechanism with the supply device 10 is required, and thus a mechanical holding mechanism is also required. On the other hand, in the second embodiment, since the storage battery 16 and the supply device 10 are in the same block, a spare battery cannot be prepared, but the above-mentioned coupling mechanism and mechanical holding mechanism are unnecessary, and this block It also has the advantage that it has sufficient mechanical strength.

The supply device of the present invention can be used for health such as recovery from fatigue, but its main application is for medical oxygen inhalation therapy. In the case of this medical use, it is better to stop the use of the storage battery 16 because it is discharged, and it may be necessary to use it again before the charging is completely completed.

In general, this type of storage battery is charged at (1C / 10) A for about 15 hours or at (1C) A for about 1.V when the nominal electric capacity (Ah) is 1C. Charging is completed by charging for 5 hours. The amount of electricity obtained by discharging is about 1/1. It becomes 5. In this example, the charging current was (1C) A for 1.5 hours.

Further, as described above, it is necessary to use the battery again during charging, and it is more preferable to have an idea of how much the storage battery is charged. The following configuration can be added as a visual aid. When the charging / discharging currents are substantially constant as in the present embodiment, the above-mentioned aim is to detect the direction of the charging / discharging current as a linear function of the charging / discharging time and to connect the timer means or the like. It can be displayed by the display means. In this embodiment, since the discharge current is about (1/2) C, the display of the meter is 100% in 1.5 hours during charging, and the display of the meter is 50% in 1 hour during discharging. It is appropriate to set the meter display to 0% for 2 hours. Also, in addition to this, it is also possible to use a liquid crystal display as the display means by combining an arithmetic element and a microcomputer. Even if this display is 0%, it is preferable that a small amount (about 5 to 10%) of electricity still remains in the storage battery.

[0029]

[Effect of device]

 By implementing the present invention, it is possible to reduce the size and weight of a portable power supply device, and to use it with any of an AC power supply, a DC power supply for an automobile, and a storage battery, and except when the storage battery is being used. The advantage of the charging device is that it can be charged even while it is in use, which can expand the range of action of the patient and contribute to further enhancement of the patient's QL.

[Brief description of drawings]

FIG. 1 is a system diagram of a supply device of the present invention.

FIG. 2 is a system diagram showing another embodiment of the supply device of the present invention.

[Explanation of symbols]

 10 Supply Device 12 Oxygen Gas Discharge Port 14 Connection Connector 16 Storage Battery 18 AC Power Supply Section 20 DC Plug 22 AC Plug 24 Respiratory Signal Connector 26 Junction Cable

Claims (6)

[Scope of utility model registration request] 1. An oxygen-concentrated gas supply device for separating and concentrating oxygen gas in air, wherein drive means for operating the oxygen-concentrated gas supply device is configured to operate with direct current power, The electric power is a storage battery, a DC power supply of a car, a DC power supply obtained by rectifying an AC power supply, and any of these DC power supplies can drive the driving means, and the storage battery can be used for the car. An oxygen-enriched gas supply device characterized in that it can be charged from either a DC power supply or a DC power supply obtained by rectifying the AC power supply. 2. The oxygen-enriched gas supply device according to claim 1, wherein the voltage of the DC power for operating the drive means is in the range of 10V to 15V. 3. The oxygen-concentrated gas supply device according to claim 1, wherein the means for separating oxygen gas in the air is a pressure fluctuation adsorption method. 4. The oxygen enriched gas supply device according to claim 1, wherein the means for separating oxygen gas in the air is a selective oxygen permeable membrane. 5. An oxygen-concentrated gas supply device for separating and concentrating oxygen gas in air, wherein a drive means for operating the oxygen-concentrated gas supply device is configured to operate with direct current power. It is characterized in that the main body of the oxygen-enriched gas supply device operated by electric power and the storage battery as a power supply or the DC power supply obtained by rectifying an AC power supply can be separated or combined with each other. The oxygen-concentrated gas supply device according to claim 1. 6. A main body of the oxygen-enriched gas supply device, wherein the driving means for operating the oxygen-enriched gas supply device is configured to operate with DC power, and the main body of the oxygen-enriched gas supply device operates with this DC power.
2. The storage battery as one block, the DC power supply unit obtained by rectifying an AC power supply as another block, and these blocks can be separated or combined with each other. Oxygen enriched gas supply device.